Didn't anyone ever tell you, there's one thing you never put in a trap if you're smart? If you value your continued existence. If you have any plans about seeing tomorrow, there's one thing you never, ever put in a trap... Me.

Didn't anyone ever tell you, there's one thing you never put in a trap if you're smart? If you value your continued existence. If you have any plans about seeing tomorrow, there's one thing you never, ever put in a trap... Me.

Didn't anyone ever tell you, there's one thing you never put in a trap if you're smart? If you value your continued existence. If you have any plans about seeing tomorrow, there's one thing you never, ever put in a trap... Me.

Didn't anyone ever tell you, there's one thing you never put in a trap if you're smart? If you value your continued existence. If you have any plans about seeing tomorrow, there's one thing you never, ever put in a trap... Me.

Didn't anyone ever tell you, there's one thing you never put in a trap if you're smart? If you value your continued existence. If you have any plans about seeing tomorrow, there's one thing you never, ever put in a trap... Me.

Didn't anyone ever tell you, there's one thing you never put in a trap if you're smart? If you value your continued existence. If you have any plans about seeing tomorrow, there's one thing you never, ever put in a trap... Me.

Didn't anyone ever tell you, there's one thing you never put in a trap if you're smart? If you value your continued existence. If you have any plans about seeing tomorrow, there's one thing you never, ever put in a trap... Me.

Didn't anyone ever tell you, there's one thing you never put in a trap if you're smart? If you value your continued existence. If you have any plans about seeing tomorrow, there's one thing you never, ever put in a trap... Me.

Didn't anyone ever tell you, there's one thing you never put in a trap if you're smart? If you value your continued existence. If you have any plans about seeing tomorrow, there's one thing you never, ever put in a trap... Me.

The Lunar Reconnaissance Orbiter Camera, or LROC, is a system of three cameras mounted on the Lunar Reconnaissance Orbiter (LRO) that capture high resolution black and white images and moderate resolution multi-spectral images of the lunar surface.

LRO is currently in the Extended Mission phase, focused on collecting the data needed to address key lunar science questions, including:1. Chronology/BombardmentDetermine bombardment history of the Moon, from the timing of basin-forming events down to small, recent impact events. Measure lunar landforms at 0.5 - 2.0 meter pixel scales for more than 10,000 targeted sites, and measure mineralogical variation of the Moon via ultraviolet-visible observations at sub-kilometer pixel scales over at least 75% of the surface.

2. Crustal EvolutionInvestigate geological processes and their role in the evolution of the lunar crust and shallow lithosphere. This investigation includes imaging of landforms at 100m scale down to meter scale for thousands of targeted regions. Obtain oblique (more than 60░ emission angle) imaging of key science targets for the purpose of assessing stratigraphy, at 2 meter pixel scales for an average of at least two targeted regions per month. Also, obtain UV/Visible (400 to 100 meter pixel scales) multi-phase angle imaging over at least 90% of the lunar surface and measure mineralogical variations of the Moon via ultraviolet-visible observations at sub-km pixel scale over a minimum of 75% of the lunar surface.

3. Regolith EvolutionLook for evidence of processes that shaped the global lunar regolith as they relate to evolution of the crust, verifying physical characteristics of the upper-most regolith layers via their textures, scattering mechanisms and composition. Measure the surface morphology at 0.5 - 2.0 meter scales, and other physical properties at meter pixel scale for specific targets.

4. Polar VolatilesInvestigate volatile sources, sinks and transfer mechanisms with emphasis on the lunar polar regions, including permanently shadowed regions (PSRs). Measure polar region landforms in PSRs at better than 20 meter horizontal scales. Also, measure reflectivity as a function of phase angle at meter and 100 meter scales near PSRs within 10░ of each pole.

The Lunar Reconnaissance Orbiter Camera, or LROC, is a system of three cameras mounted on the Lunar Reconnaissance Orbiter (LRO) that capture high resolution black and white images and moderate resolution multi-spectral images of the lunar surface.

LRO is currently in the Extended Mission phase, focused on collecting the data needed to address key lunar science questions, including:1. Chronology/BombardmentDetermine bombardment history of the Moon, from the timing of basin-forming events down to small, recent impact events. Measure lunar landforms at 0.5 - 2.0 meter pixel scales for more than 10,000 targeted sites, and measure mineralogical variation of the Moon via ultraviolet-visible observations at sub-kilometer pixel scales over at least 75% of the surface.

2. Crustal EvolutionInvestigate geological processes and their role in the evolution of the lunar crust and shallow lithosphere. This investigation includes imaging of landforms at 100m scale down to meter scale for thousands of targeted regions. Obtain oblique (more than 60░ emission angle) imaging of key science targets for the purpose of assessing stratigraphy, at 2 meter pixel scales for an average of at least two targeted regions per month. Also, obtain UV/Visible (400 to 100 meter pixel scales) multi-phase angle imaging over at least 90% of the lunar surface and measure mineralogical variations of the Moon via ultraviolet-visible observations at sub-km pixel scale over a minimum of 75% of the lunar surface.

3. Regolith EvolutionLook for evidence of processes that shaped the global lunar regolith as they relate to evolution of the crust, verifying physical characteristics of the upper-most regolith layers via their textures, scattering mechanisms and composition. Measure the surface morphology at 0.5 - 2.0 meter scales, and other physical properties at meter pixel scale for specific targets.

4. Polar VolatilesInvestigate volatile sources, sinks and transfer mechanisms with emphasis on the lunar polar regions, including permanently shadowed regions (PSRs). Measure polar region landforms in PSRs at better than 20 meter horizontal scales. Also, measure reflectivity as a function of phase angle at meter and 100 meter scales near PSRs within 10░ of each pole.

The Lunar Reconnaissance Orbiter Camera, or LROC, is a system of three cameras mounted on the Lunar Reconnaissance Orbiter (LRO) that capture high resolution black and white images and moderate resolution multi-spectral images of the lunar surface.

LRO is currently in the Extended Mission phase, focused on collecting the data needed to address key lunar science questions, including:1. Chronology/BombardmentDetermine bombardment history of the Moon, from the timing of basin-forming events down to small, recent impact events. Measure lunar landforms at 0.5 - 2.0 meter pixel scales for more than 10,000 targeted sites, and measure mineralogical variation of the Moon via ultraviolet-visible observations at sub-kilometer pixel scales over at least 75% of the surface.

2. Crustal EvolutionInvestigate geological processes and their role in the evolution of the lunar crust and shallow lithosphere. This investigation includes imaging of landforms at 100m scale down to meter scale for thousands of targeted regions. Obtain oblique (more than 60░ emission angle) imaging of key science targets for the purpose of assessing stratigraphy, at 2 meter pixel scales for an average of at least two targeted regions per month. Also, obtain UV/Visible (400 to 100 meter pixel scales) multi-phase angle imaging over at least 90% of the lunar surface and measure mineralogical variations of the Moon via ultraviolet-visible observations at sub-km pixel scale over a minimum of 75% of the lunar surface.

3. Regolith EvolutionLook for evidence of processes that shaped the global lunar regolith as they relate to evolution of the crust, verifying physical characteristics of the upper-most regolith layers via their textures, scattering mechanisms and composition. Measure the surface morphology at 0.5 - 2.0 meter scales, and other physical properties at meter pixel scale for specific targets.

4. Polar VolatilesInvestigate volatile sources, sinks and transfer mechanisms with emphasis on the lunar polar regions, including permanently shadowed regions (PSRs). Measure polar region landforms in PSRs at better than 20 meter horizontal scales. Also, measure reflectivity as a function of phase angle at meter and 100 meter scales near PSRs within 10░ of each pole.